A system and method for evaluating dental treatment utilizes virtual models created from scanned plaster casts. patient's teeth are directly scanned with a three dimensional scanner or plaster casts of the patient teeth following treatment are scanned for evaluation. A planned configuration based on a plaster cast prior to treatment is created and the desired position and the two models are compared so that the actual position of the teeth may be compared to the desired position after treatment. Superimposition of the virtual models provides accurate and precise measurement of variances between the two virtual models. Difficulties due to superimposing the models, which are of the entire arch and evaluations based on individual teeth are overcome by applying an iterative closest point algorithm to correct the position and provide a truer measurement for evaluation. Differences between a preferred position of a patient's teeth and actual position of a patient's teeth may be assigned a score and the score may be compared to other patients to rank the patient needs.
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1. A method of quantifying corrective tooth positioning, comprising:
creating a first virtual model of an actual position of a patient's teeth;
creating a second virtual model of a preferred position of a patient's teeth after orthodontic treatment; superimposing the first and second virtual models;
performing a best fit process for fitting corresponding teeth of the first and second virtual models and moving one of the teeth accordingly;
evaluating the differences in position of the teeth of the first and second virtual models;
scoring the differences and assigning a score to each patient; and
prioritizing patient needs based on the score assigned.
7. A method of evaluating corrective tooth positioning, comprising:
creating a first virtual model of a preferred position of the teeth after orthodontic treatment;
creating a second virtual model of an actual position of the teeth after treatment;
superimposing the first and second virtual models; performing a best fit process for fitting corresponding teeth of the first and second virtual models and moving one of the teeth accordingly;
evaluating the differences in position of the teeth of the first and second virtual models; and
applying a three dimensional coordinate system to individual teeth and shifting the three dimensional coordinate system by the closest point algorithm.
15. A method of evaluating corrective tooth positioning, comprising:
creating a first virtual model of a portion of the patient's teeth prior to treatment;
creating a second virtual model of a preferred position of the teeth after orthodontic treatment;
creating a third virtual model of an actual position of the teeth after treatment;
superimposing the second and third virtual models;
performing a closest point algorithm and fitting corresponding teeth of the second and third superimposed virtual models and moving at least one of the teeth accordingly;
evaluating the differences in position of the teeth of the first and second virtual models; and
creating a fourth virtual model at a time subsequent to creating the third virtual model and comparing the fourth virtual model to the second virtual model.
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This application is being filed on 4 May 2007, as a PCT International Patent application in the name of Robert J. Isaacson, Bruce Willard Hultgren, Michael-Craig Marshall, and James E. Beauchamp, all citizens of the U.S., applicants for the designation of all countries, and claims priority to U.S. Provisional Patent Application No. 60/798,464, filed May 4, 2006.
1. Field of the Invention
The present invention is directed to a system and method for evaluating orthodontic treatment in an objective manner by comparing virtual models of teeth following orthodontic treatment to a targeted alignment.
2. Description of the Prior Art
Evaluation of patient's needs and treatment is invaluable for determining a prognosis and diagnosis for the patient. Precise and accurate measurement of a patient's teeth is needed for diagnosis and for evaluation. Traditional methods require locating selected patient structures and using the structures as landmarks. The use of landmarks has built in imprecision as there is some imprecision in locating the landmark twice. The problem is compounded when the landmark must be located after growth and/or treatment. Therefore, it has been difficult for practitioners to quantify and rate severity or to quantify treatment success.
Evaluation and grading also is important for ensuring that orthodontic practitioners are performing satisfactorily. In order to ensure quality standards are maintained, the American Board of Orthodontics (ABO) certifies members who pass a stringent examination including a clinical examination. The clinical examination currently involves reviewing casts from patients to assess the success and quality of the treatment provided. An objective grading system has been developed to evaluate final dental casts and radiographs. Criteria and areas evaluated include alignment, marginal ridges, buccolingual inclination, occlusal relationships, occlusal contacts, overjet, interproximal contacts and root angulation.
The evaluation is conducted by a group of members of the American Board of Orthodontics utilizing a specially developed measuring gauge. Members of the ABO involved in grading the clinical examination take measurements on various locations on several sets of plaster casts presented by candidates seeking certification. Graders make determinations regarding deviation from a desired result and points are awarded according to the success of the treatment. A score is then assigned for the clinical examination.
For each candidate, ten or more cases may be evaluated. For each case, the upper arch and lower arch are measured, meaning that more than twenty sets of measurements are made and compared for each candidate. It can be appreciated that with many candidates seeking certification and a number of graders involved in the certification, the clinical examination grading process is a time consuming endeavor than can take hundreds of man hours for each examination.
In addition to being time consuming, the examination process has several flaws. The manual measurements that are made may not be consistent from grader to grader. Precisely locating landmarks for reference points used in comparison is challenging. In addition, there is subjectivity with regard to the results and further inaccuracies that may be incorporated from the measurement process. Due to these drawbacks, it is possible for some candidates who should pass the certification process to be failed while others may pass that should not.
It can be seen that a new and improved system and method for quantifying the severity of a patient's condition and for grading orthodontic treatment is required. In addition, a method and system is needed that provides a precise and objective evaluation with a numerical rating comparing the position of the teeth to an ideal position. Such a system should eliminate the need to use traditional landmarks to make measurements while increasing accuracy and consistency over prior art manual measuring systems. Moreover, such a system should provide for greater precision than is possible with the current systems. Such a system should eliminate the need for each grader to manually measure and evaluate the final occlusion and allow all graders to utilize an accurate virtual model. Such a system should save time and effort over current systems. In addition, such an evaluation system and method should provide an electronic model suitable for use beyond grading for examination purposes. The present invention addresses these problems, as well as others associated with evaluation of orthodontic treatment.
The present invention is directed to a system and method for evaluating the success of orthodontic treatment with electronic modeling. According to the present invention, digital models of a patient's teeth are created prior to treatment. A treatment plan is then formulated and an electronic plan with an idealized model is created with a digital representation of a final ideal position of the teeth.
The three dimensional digital model of the patient's teeth following treatment is then superimposed with the idealized model. As there are inconsistencies with superimposing the entire arch, which is treated as a single element, certain individual teeth may appear to be unduly out of alignment. Therefore, a best fit matching process is performed utilizing data of the coordinates representing the teeth. The matching program uses a best fit algorithm, such as an iterative close point algorithm to move each of the teeth individually for matching. It has been found that the algorithm typically needs to be run five times and there is virtually no movement of the teeth after ten iterations. The moved teeth are then superimposed and variances are measured. The variances can then be represented in a three dimensional electronic image. It can be appreciated that the position and translation of a tooth and its coordinate system may be changed by the closest point matching algorithm. However, it has been found that the matching process compensates for possible errors due to matching a cast of the entire arch.
Following application of the matching program, the electronic images are superimposed with a mesh of measurement points on the surface of the tooth matched for evaluation. The virtual model can accurately and precisely measure the virtual distance between the measurement points in three dimensions and that distance is determined for each point. A numerical score may then be assigned corresponding to the variance. Variances for all the grading criteria are then determined and scores assigned. The numerical scores for all the criteria and all the teeth may then be added together to give a final score for evaluation. This data and the assigned scores are then utilized for evaluating the overall success of the treatment.
In addition to measuring the differences between an actual position and an ideal position of a tooth or other structure, it is also advantageous to evaluate the fit of the teeth. The contacts points of a patient's idealized teeth can be compared to actual contact points as the contact points can be precisely captured with scanning to create the virtual models.
A numerical score may also be given between the idealized model and the model taken before treatment. This score provides for an objective evaluation of the severity of the corrections needed and may be used to prioritize treatment, expenditures, likelihood of success and/or to compare the needs of one patient as compared to another.
These features of novelty and various other advantages that characterize the invention are pointed out with particularity in the claims annexed hereto and forming a part hereof. However, for a better understanding of the invention, its advantages, and the objects obtained by its use, reference should be made to the drawings that form a further part hereof, and to the accompanying descriptive matter, in which there is illustrated and described a preferred embodiment of the invention.
Referring now to the drawings and in particular to
More recently, high resolution three dimensional scanners have been developed that provide three dimensional craniofacial imaging that may be used to create a digital representation of a patient's teeth with a high degree of precision without plaster casts and without using landmarks or markers. Such scanners include cone beam tomography scanners, intra-oral scanners, CT scanners and other technologies that provide high resolution precision three dimensional digital models. Examples of commercially available scanners include cone beam scanners sold under the trade names ILUMA™ from Kodak and i-CAT from Imaging Sciences International. Cone beam tomography scanners are well suited for such applications as they emit lower radiation than traditional dental x-rays and may eliminate the need for creating plaster casts.
It can be appreciated that plaster casts are currently taken before and after treatment and used for grading by the American Board of Orthodontics. The before and after plaster casts may be digitized and stored. Based on the original casting before treatment, a desired treatment outcome may be created from the digital model by moving each of the teeth to a desired position and alignment 30 such as shown in
It can also be appreciated that such a virtual model 30 representing desired results of treatment shown in
In addition, to movement of each tooth and other structures is the occlusion between the upper and lower teeth that affects the patient's bite. The virtual models provide a precise location of contact points 28, shown in
For treatment, each tooth has a mesh of selected points, preferably on the top of the tooth, that are selected. The tooth is also assigned an XYZ coordinate system based on its shape and the measurement points in the mesh. This is shown for example, in
The arch of the electronic plan 30 is then superimposed on the virtual model of the patient's post treatment arch 40. When the arches are superimposed, individual differences between the teeth can be measured with great precision in three dimensions using the electronic digital model. Such variances are shown in
An example of a suitable best fit program is an iterative closest point algorithm. The iterative closest point algorithm is an iterative alignment algorithm that works in three phases: 1) establish correspondence between pairs of features in the two structures that are to be aligned based on proximity, 2) estimate the rigid transformation that best maps the first member of the pair onto the second and then 3) apply that transformation to all features in the first structure. These three steps are then reapplied until convergence is concluded. Although simple, the algorithm works quite effectively when given a good initial estimate.
More precisely, such a point matching algorithm is represented by:
Let be a set of Ns points {{right arrow over (s)}1, . . . , {right arrow over (s)}N
The basic algorithm has been previously extended in a number of ways: 1) correspondence between a point and a tangent plane to overcome the lack of an exact correspondence between the two sets, 2) robustifying the algorithm to the influence of outliers and features lacking correspondences, 3) using a weighted least-square error metric, and 4) matching between features using a metric trading off distance and feature similarity (based local shape invariances). All of these approaches assume a rigid Euclidean transformation between the corresponding features, whereas the method presented here uses projective correspondence.
This process is known as “wiggling” and is believed to provide a truer representation of the success of treatment. The application of the closest point algorithm to each tooth provides a best fit with the corresponding teeth between the virtual model of the actual teeth and the electronic plan. It has been found that the comparison and evaluation after a best fit matching provides a truer and more accurate measurement of the treatment that removes possible problems introduced by matching the virtual model of an entire arch wherein individual teeth may not be accurately oriented and positioned. The algorithm is applied iteratively and it has been found that application of between 5 and 10 iterations provide more than satisfactory results.
As shown in
The assigned scores can be used for multiple purposes including grading for certification of practitioners. In addition, the assigned scores can be used for comparing the needs of different patients and ranking the need for treatment. Where dental care is limited or priority must be assigned to each patient, the present invention provides a more objective measure than is possible with prior art methods and systems. The objective ranking can also be used for evaluation of the likelihood of success and to evaluate cost effectiveness for various patient needs. The objective scoring also allow for making a virtual model after a period of time has passed and performing an evaluation. Such subsequent evaluation provides for studying the effects of normal usage over time and/or growth as compared to an idealized model.
It can be appreciated that cone beam computer tomography and digitizing of a plaster cast through precision digital scanning eliminates measurement differences and inaccuracies due to imprecision with location of the measuring devices. Moreover, the program may be run quickly without requiring individual graders to manually perform measurements and the raw data or processed data with scores may be supplied to all graders.
It can further be appreciated that inaccuracies due to difficulties in superimposing a patient's arch onto a proposed arch following orthodontic treatment are compensated with a best match process being applied to each of the teeth. Inaccuracies from consistently locating landmarks are also eliminated with the present invention. This system also eliminates the need for maintaining plaster casts for evaluation and grading and difficulties with storing and transporting such plaster casts for the measurement and grading.
It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Marshall, Michael C., Hultgren, Bruce W., Isaacson, Robert J.
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